def screwMotion(self):
     l = self.vector.length()
     if l == 0.:
         return Geometry.Vector(0.,0.,0.), \
                Geometry.Vector(0.,0.,1.), 0., 0.
     else:
         return Geometry.Vector(0., 0., 0.), self.vector / l, 0., l
 def screwMotion(self):
     axis, angle = self.rotation().axisAndAngle()
     d = self.vector*axis
     x = d*axis-self.vector
     if abs(angle) < 1.e-9:
         r0 = Geometry.Vector(0., 0., 0.)
         angle = 0.
     else:
         r0 = -0.5*((N.cos(0.5*angle)/N.sin(0.5*angle))*axis.cross(x)+x)
     return r0, axis, angle, d
 def asVector(self):
     """
     @returns: an equivalent vector object
     @rtype: L{Scientific.Geometry.Vector}
     @raises ValueError: if rank > 1
     """
     from Scientific import Geometry
     if self.rank == 1:
         return Geometry.Vector(self.array)
     else:
         raise ValueError('rank > 1')
 def screwMotion(self):
     axis, angle = self.rotation().axisAndAngle()
     d = self.vector * axis
     if d < 0.:
         d = -d
         axis = -axis
         angle = -angle
     if abs(angle) < 1.e-9:
         r0 = Geometry.Vector(0., 0., 0.)
         angle = 0.
     else:
         x = d * axis - self.vector
         r0 = -0.5 * (
             (N.cos(0.5 * angle) / N.sin(0.5 * angle)) * axis.cross(x) + x)
     return r0, axis, angle % (2. * N.pi), d
 def axisAndAngle(self):
     """
     @returns: the axis (a normalized vector) and angle (in radians).
               The angle is in the interval (-pi, pi]
     @rtype: (L{Scientific.Geometry.Vector}, C{float})
     """
     asym = -self.tensor.asymmetricalPart()
     axis = Geometry.Vector(asym[1, 2], asym[2, 0], asym[0, 1])
     sine = axis.length()
     if abs(sine) > 1.e-10:
         axis = axis / sine
         projector = axis.dyadicProduct(axis)
         cosine = (self.tensor - projector).trace() / (3. - axis * axis)
         angle = angleFromSineAndCosine(sine, cosine)
     else:
         t = 0.5 * (self.tensor + Geometry.delta)
         i = N.argmax(t.diagonal().array)
         axis = (t[i] / N.sqrt(t[i, i])).asVector()
         angle = 0.
         if t.trace() < 2.:
             angle = N.pi
     return axis, angle
Exemplo n.º 6
0
junk = co_file.readline()

testline = co_file.readline()

while testline != "":
    # Eliminate white space and split line
    in_str = testline.strip()
    in_str = in_str.split()

    #Convert coordinates based on atom type

    if (in_str[0] == "H" and len(H1) == len(H2)):

        #Convert coordinates to vectors for the H1's
        H1.append(
            Geo.Vector(float(in_str[1]), float(in_str[2]), float(in_str[3])))
        print "H1"

    elif (in_str[0] == "H" and len(H2) == (len(H1) - 1)):

        #Convert coordinates to vectors for the H2's
        H2.append(
            Geo.Vector(float(in_str[1]), float(in_str[2]), float(in_str[3])))
        print "H2"

    elif (in_str[0] == "O"):

        #Convert coordinates to vectors for the O's
        Oxy.append(
            Geo.Vector(float(in_str[1]), float(in_str[2]), float(in_str[3])))
        print "O"
 def screwMotion(self):
     axis, angle = self.axisAndAngle()
     return Geometry.Vector(0., 0., 0.), axis, angle, 0.
 def translation(self):
     return Translation(Geometry.Vector(0., 0., 0.))
    def inverse(self):
        return LinearTransformation(self.tensor.inverse(), -self.vector)


# Utility functions


def angleFromSineAndCosine(y, x):
    return atan2(y, x)


def mod_angle(angle, mod):
    return (angle + mod / 2.) % mod - mod / 2


# Test code

if __name__ == '__main__':

    t = Translation(Geometry.Vector(1., -2., 0))
    r = Rotation(Geometry.Vector(0.1, -2., 0.5), 1.e-10)
    q = r.asQuaternion()
    angles = r.threeAngles(Geometry.Vector(1., 0., 0.),
                           Geometry.Vector(0., 1., 0.),
                           Geometry.Vector(0., 0., 1.))
    c = t * r
    print c.screwMotion()
    s = Scaling(2.)
    all = s * t * r
    print all(Geometry.ex)
Exemplo n.º 10
0
junk = xyz_file.readline()
junk = xyz_file.readline()

while 1:
    line = xyz_file.readline()
    if not line: break

    x, y, z = map(float, string.split(line)[1:]) #ignore atom label
    cage_type = string.split(line)[0] #get the atom type

    #Convert coordinates based on atom type

    if (cage_type == "Ar(Small)"):

        #Convert coordinates to vectors for the Small Cages
        small_cages.append(Geo.Vector(x,y,z))

    elif (cage_type == "Kr(Large)"):

        #Convert coordinates to vectors for the Large Cages
        large_cages.append(Geo.Vector(x,y,z))

    else:

        raise CorrelationError("Can't parse file. Encountered strange cage centre type: " + cage_type + " Only 'Ar(Small)' and 'Kr(Large)' accepted.")

xyz_file.close()

print "Read in Cage Centre locations. There are %d small and %d large cages." % (len(small_cages), len(large_cages))